Noise balancing circuits



Dec. 2, 1952 RIB. DOME 2,620,439

' I NOISE BALANCING CIRCUITS Filed Nov. 5, 1947 InVentor-z- Robert B. Dqme,

byMdM f His Attprney.

Patented Dec. 2, 1952 unit-co ears/NT G FF I GE "2,620Q4'3'9 Noi'sii BALANCING QIRGUITs Robert 'B.';- Dome, -Geddes Townshim Onondaga County, -N.'Y,, assignor to General Electric com any, a,-1Etifpbratiori of 'New York A1'ipli a'jti6l'x'Nm 'mber 5, 'IB IYQ S an all No. 78451 56 3 Claims.

My invention relates to nois'ebalancingcircuits, and mo're particul'arly, to such circuits as may be incorporated in "amplitude i modulation radio receivers and the like.

Inthe case-of an amplitudamodula-tion radio receiver, it is desirable to minimize random noise interference from the sound-output "appea'ring "at the loudspeaker. This noise interference takes the form "of random amplitude modulation, "and may be caused, for example, "by "automobile ignitionsy'stems and ithe like. It is a primary object of'myinventiontozprovide -improved means for "suppressing such noise 'interferen'cein the output of'an' amplitude modui lation radio' receiver.

In'='genera1, there aretwo methods foraccomplishing such 'noi'sesuppression. Themore re- "eent"developmentshave been directe'd to noise -'liininati'on bymeans of peak'clippers or limiters. 'Thehthenihethod is that whereina sample of frequency spectrum containing both thefde'sired signal and the undesired noise; and a: sample of frequency-spectrum" containing onlynoise modulatio'n, are balahced so that only the desired "signal remains. It is 'aipartic'ular 'object 'of my in'venticin" to provide improved noise suppression a "means 'of' the latter type. I

It is a further" object of my invention" to p'ro- '-'v'ide improved means for "detecting -amplitude- "modulat'ed waves "while substantial-1y eliminatin extraneous noise from the output. The features of my invention"which'= I be'lieve to be novel areset-forthwithiparticularity in the appended claims. My invention itself, however, together with further" obj ects-"and-"adVantages' thereof, may best be understood-by refer- 'dtiSf. The ancde 5 0fdevice |---iS connected "to i a' sui t'able source of 'dire'ct eperating' 130-- fiitial +13- thluha 'p'ai aillel rescnant circuit s 'ccmpnsing ailnductance i-ar-id a canadt n suitable source -01: 'ajmplitude ri lddiilated '1 te'rmdiate frequency -sig n'al voltage. r wh'ich may; for example; comprise the converter-mixer ---s"tagebfa superhetercdyne'r'eceiver (not shown) isconnectedto the controlgri'd il of device I.

The suppressor grid ii] 'is directly connected to the cathode 2 in the-cust'omary manner, and thescreengrid H is connected to-the source of direct energizing voltage '+B; the conventional screenbypass-condenser i2 is also provided.

'A frequency discriminating transformer or discriminator transformer 13 is provided, the primary circuitof which comprises the parallel resonant circuit 6 in'the'an'ode circuit of the intermediate irequencyamplifier I. 'natortransformer l3 also comprises a secondary parallel resonant circuit UL comprising an in- The discrimiductan'ceIS-and a capacitance [6. A coupling 'condenser'i'lisconnected between the anode 5 of device I and acentertap i8 7 onthe secondary inductance 'ifij-which'tapis grounded through a resistance l9. The-secondary 'para-llel resonant circuit "M is 'conne'cted in series-between The Improved balancemay-"be obtainedxbyreplacingthe' coupling'resistances 33,' 34 with a'single "resistance?potentiometer'fhavin a variable tap, "notflshovvn. In' thismodi'ficatiOn, resistance 49 is connected between the variable tap I and ground. In-this manner, theoutputcmay be balanced "independently of the manufacturing sistances. Audio frequency output voltage ap- "Dears acrcssresis'tance was before.

tolerances-normally encountered in separate relt will be seen that theportion of the'circuit thus i'ar described is essentially that of an in- '-termediate frequency amplifier and a balanced discriminatorsuch as "might be employed in a frequency modulation'radioreceiver. -As is wellknown in theart, such a balanceddiscriminator circuit has V a substantial-1y lin'e'ar detection characteristic throughout a *fi-Xed --band -of ire- -quencies. In-accordance-with my invention, the "balanced discriminator functions as "an' ampli- 'tude detector in an amplitude modulation receiver; and simultaneously operates -to'- reduce random noise interference. -In operation, the'receiver-is tuned-toadeacme-es differs from the intermediate carrier frequency of the desired intelligence. As is well-known, amplitude-modulated signals of a carrier frequency equal to the balance frequency of the discriminator are balanced out by the detectors 2|, 23; amplitude-modulated signals of a frequency not corresponding to the discriminator characteristic mid-frequency, but within the discriminator bandwidth, are detected unequally by the diodes 2!, 23. Consequently, owing to the unbalance, the desired signals produce demodulated audio voltages in the discriminator output,

while much of the undesired noise is eliminated from the output.

For example, let the secondary circuit i l be tuned to a resonant frequency of 8.25 megacycles per second, and assume a bandwidth of 100 kilccycles per second. If the intermediate frequency signal is adjusted by means of the local oscillator to 8.29 megacycles per second, such a frequency being within the bandwidth of the secondary circuit [4, the signal is impressed on the discriminator characteristic at a point to one side of the balance point, and is consequently demodulated unequally by the diodes 2!, 23. As a result, unequal detected audio-frequency signal voltages appear across the diode load resistances 26, 21, and the net voltage is transferred to terminal 3i Furthermore, any irnpulse noise, such as that produced by an automobile ignition system, for example, shock-excites the secondary circuit M at its own resonant frequency of 8.25 megacycles per second in the case of the example under consideration. This frequency, however, is the balance frequency of the detectors 22, 23. Consequently, substantially equal and oppositely polarized extraneous noise voltages appear across the load resistances 26, 2'1, and the net voltage is transferred as zero voltage to terminal 363. Furthermore, this noise balancing is obtained without the use of limiters or peak clippers, and improved fidelity of sound output is obtained.

As a further modification, automatic volume control voltage is supplied to the preceding tubes by connecting an audio frequency low pass filter, comprising a series resistance 35 and a shunt capacitance 36, to the anode 24 of diode 2| in the customary manner. A unidirectional voltage appears across the filter condenser 36, which voltage may be applied to the control grids of preceding intermediate frequency or radio frequency stages for control purposes.

In order always to insure tuning to the Same side of the balance point, I provide an auxiliary circuit comprising two audio amplifier tubes 31, 33, respectively. The control grid 39 of tube 31 is connected to the anode 24 of diode 2i and to the cathode 25 of diode 23 through respective high resistances 40, 4!. The control grid 33 of tube 31 is bypassed for audio frequencies by a condenser 42. The cathodes 43, 44 of tubes 31,

38 are connected directly together and utilize a common cathode bias resistance 45. The anodes it, ll of amplifier tubes 31, 38 are connected to a source 'of positive direct operating potential +B, a load resistance 48 being included in series in the case of the latter anode. The terminal point 3c is grounded through a resistance potentiometer t9, the movable tap 59 of which is connected to the control electrode 51 of amplifier tube 33.

In general, this auxiliary circuit functions always to insure tuning of the local oscillator so as to produce an intermediate frequency on the same side of the balance point of the balanced detector circuit. The direct components of voltages appearing across the load resistances 2B, 21 are used to bias an audio amplifier tube beyond cutoff if the intermediate signal frequency is produced by tuning the local oscillator in the improper direction.

In particular, the direct voltages across the load resistances 2%, 27 are parallel through the grid coupling resistances :39, ti, and are applied to the control electrode 39 of a tube 31. As long as the resultant grid voltage of tube 31 is sufficiently negative, tube 3? is biased beyond cutoff and anode current fiows in the audio amplifier tube 38, audio-frequency output appearing across the load resistance 18. If, however, the signal is impressed on the balanced detector circuit in such a way that diode 23 receives the largest portion of signal voltage, the bias voltage applied to tube 3? is made more positive, and anode current flows in tube 37, rendering the audio amplifier tube 38 non-conductive by virtue of the common cathode bias potential developed across resistor 45. Hence, audio output appears between terminals 52, 53 across the amplifier load resistance at only when the local oscillator is tuned in such a manner as to apply the larger portion of the signal voltage to diode 2!.

In actual tests made on this circuit, I have found a reduction in extraneous noise appearing in the sound output of an amplitude modulation broadcast receiver of the order of 10 to 1, i. e., with a desired signal of 1 volt, the noise output was 10 volts with the conventional Single detector, but noise output was only 1 volt with the balanced detector circuit shown in the figure.

While I have shown and described a present preferred embodiment of my invention, it will be understood that numerous variations and modifications may be made, and I contemplate, in the appended claims, to cover any equivalent variations and modifications as fall within the true spirit and scope of my disclosure.

What I claim as new and desire to secure by Letters Patent of the United States is:

1. In an amplitude-modulation receiver of the superheterodyne type, means for obtaining an output signal substantially free of extraneous noise comprising an intermediate-frequency amplifier tuned to amplify a first predetermined frequency and to amplify signals extending over a predetermined frequency band including said frequency, a balanced frequency discriminator circuit comprising an input circuit coupled to said amplifier and tuned to a second predetermined frequency also lying within said band but different from said first frequency, said discriminator circuit including a pair of rectifiers having opposed output load impedances, said discriminator being constructed and arranged to produce unidirectional output voltages across said impedances of opposite polarities and of differentially-varyin magnitudes in response to signals impressed on said input circuit, said voltages being equal for voltages of said second predetermined frequency, means for impressing an amplitude modulated intermediate frequency carrier Wave on said amplifier, said carrier wave having said first predetermined frequency, a modulation-frequency signal amplifier having an input circuit, and means differentially coupling both said load impedances to the input circuit of said signal amplifier soas to impress said detected output voltages thereon in opposition.

2. A noise-reducing demodulating circuit for an amplitude-modulation radio receiver of the type having means for converting a received carrier wave into a Wave of a first predetermined intermediate frequency, comprising a channel for amplifying said intermediate frequency wave, said channel having a frequency response extending over a band including said frequency, a balanced frequency discriminator connected to said channel and tuned to a second predetermined frequency lying within said band, said discriminator having a pair of opposed output load impedances and being constructed and arranged to produce a unidirectional output voltage having polarity and magnitude respectively dependent on the direction and magnitude of the deviation in frequency of applied waves from said second predetermined frequency, said second frequency differing from said first frequency, an amplifier coupled to both said output load impedances for amplifying said output voltage, and means for rendering said amplifier operative When said voltage is of one polarity and inoper ative when of opposite polarity, whereby only the output voltage of said one polarity is amplified.

3. A noise reducing demodulating circuit for an amplitude modulation radio receiver of the type having means for converting a received carrier wave into an intermediate frequency wave, comprising a channel for amplifying said intermediate frequency wave, said channel having a substantially uniform response over a predetermined range of frequencies, a balanced frequency discriminator circuit connected to said channel, said circuit having primary and secondary windings tuned to a selected frequency within said range and having a fixed bandwidth, said intermediate frequency differing from said selected frequency but occurring within said range 6 and Within said bandwidth, said circuit including a pair of rectifiers connected to said secondary winding and having unlike poles connected together through a pair of resistances whose junction is connected to a common point in said circuit, an impedance connected between said common point and the midpoint of said secondary winding, and means for impressing voltage from said primary winding on said point, whereby said intermediate frequency Wave produces at said unlike poles unidirectional voltages of opposed polarity and unequal magnitudes varying in accordance with said amplitude modulation, an amplifier having a connection to said common point and having a signal input terminal, a polarity sensitive amplification control terminal, and a signal output terminal, said signal input terminal being connected by a pair of irnpedances to said unlike poles, said control terminal being connected to said unlike poles by a pair of impedances, said impedances passing low frequency and unidirectional components only to control the amplification of said amplifier in accordance with the polarity of said unidirectional voltages. 6

ROBERT B. DOME.

REFERENCES CETED The following references are of record in the file of this patent:

UNITED STATES PATENTS Number Name Date 1,559,743 De Bellescize Nov. 3, 1925 2,121,103 Seeley June 21, 1938 2,176,218 Klutke Oct. 17, 1939 2,204,954 Anderson et al. June 18, 1940 2,227,415 Wolff Dec. 31, 1940 2,290,517 Wilson July 21, 1942 2,361,625 Hansell Oct. 31, 1944 2,362,806 Dome Nov. 14, 1944 2,497,103 Toth Feb. 14, 1950 FOREIGN PATENTS Number Country Date 552,807 Great Britain Apr. 27, 1943 4,125 Great Britain Nov. 4, 1909 OTHER REFERENCES Tuning Indicators and Circuits for Frequency- Modulation Receivers by Rodgers; Pro. IRE March 1943, pages 89 to 93. 

